Investigating the Performance of a Seasonal Cold Storage System for Dry and Mountainous Climates

Document Type : Original Article

Authors

1 Mechanical and Aerospace Systems Research Group, University of Nottingham, Nottingham NG7 2TU, UK

2 Department of Mechanical Engineering, Tafresh University, Iran

3 School of Engineering, Macquarie University

4 Faculty of electrical engineering, Tafresh University

Abstract

Seasonal cold storage presents an eco-friendly and highly efficient solution for capturing natural or artificial cold energy during winter, which can then be utilised for cooling during summer. This research proposes an innovative cold storage system tailored for mountainous climates. The system harnesses refrigeration technology and cold ambient air to produce ice, offering a sustainable approach to glacier recovery. Additionally, the stored water within the ice storage system reduces surface water evaporation in arid, high-altitude regions. In this study, we detail the performance of the proposed system and examine its effectiveness using climate-specific equations for the Tafresh region. The system operates with a 5 kW refrigeration cycle and fans to direct cold air into the storage compartment at optimal speeds when the ambient temperature reaches -3°C. For the case study presented, the system not only decreased energy consumption by 13.73% during the summer months and reduced operational costs by 8%, but it also conserved 150 m³ of water, transferring it from the rainy season to the warmer months. Furthermore, the system successfully achieved peak load shaving of 2 kW during peak demand periods. This study highlights the system’s dual benefits in energy conservation and water management, making it a compelling solution for sustainable cooling in mountainous regions.

Keywords

References

  • Pinel, P., Cruickshank, C. A., Beausoleil-Morrison, I., & Wills, A. (2011). A review of available methods for seasonal storage of solar thermal energy in residential applications. Renewable and Sustainable Energy Reviews, 15(7), 3341–3359. doi:10.1016/j.rser.2011.04.013.
  • Johari, A., Hashim, H., Ramli, M., Jusoh, M., & Rozainee, M. (2011). Effects of fluidization number and air factor on the combustion of mixed solid waste in a fluidized bed. Applied Thermal Engineering, 31(11–12), 1861–1868. doi:10.1016/j.applthermaleng.2011.03.013.
  • Quaranta, E., & Revelli, R. (2018). Gravity water wheels as a micro hydropower energy source: A review based on historic data, design methods, efficiencies and modern optimizations. Renewable and Sustainable Energy Reviews, 97, 414–427. doi:10.1016/j.rser.2018.08.033.
  • Ardhali, M. (2016). Cooling energy technology and energy management in buildings. Proceedings of the Second National Iranian Energy Conference, 18-19 February, 2016, Takestan, Iran. (In Persian).
  • Yan, C., Shi, W., Li, X., & Wang, S. (2016). A seasonal cold storage system based on separate type heat pipe for sustainable building cooling. In Renewable Energy (Vol. 85). Tsinghua University. doi:10.1016/j.renene.2015.07.023.
  • Johansson, P. (1999). Seasonal cold storage in rock caverns. Master Thesis, Luleå University of Technology, Luleå, Sweden.
  • Skogsberg, K. (2002). The Sundsvall Regional Hospital snow cooling plant—results from the first year of operation. Cold Regions Science and Technology, 34(2), 135–142. doi:10.1016/s0165-232x(01)00067-2.
  • Klassen, J. (1981). Project icebox and annual energy storage system. ASHRAE Transactions, 1456-1460.
  • Francis, C. E., & Tamblyn, R. T. (1987). Annual cycle ice production and storage. ASHRAE Transactions, 1760-1765.
  • Alwan, A., & Hameed, R. H. (2017). Methodology design to predict the solidification process of pure water inside a cylindrical enclosure. International Journal of Thermal Technologies, 7(1).
  • Singh, R., Mochizuki, M., Mashiko, K., & Nguyen, T. (2011). Heat pipe-based cold energy storage systems for data center energy conservation. Energy, 36(12), 661–673. doi:10.1016/j.energy.2011.05.006.
  • Popov, A. P., Vaaz, S. L., & Usachev, A. A. (2010). Review of the Current Conditions for the Application of Heat Pipes (Thermosyphons) To Stabilize the Temperature of Soil Bases Under Facilities in the Far North. Heat Pipe Science and Technology, An International Journal, 1(1), 89–98. doi:10.1615/heatpipescietech.v1.i1.60.
  • Paredes-Sánchez, J. P., García-Elcoro, V. E., Rosillo-Calle, F., & Xiberta-Bernat, J. (2016). Assessment of forest bioenergy potential in a coal-producing area in Asturias (Spain) and recommendations for setting up a Biomass Logistic Centre (BLC). Applied Energy, 171, 133–141. doi:10.1016/j.apenergy.2016.03.009.
  • Wijaya, M. E., & Tezuka, T. (2013). Measures for improving the adoption of higher efficiency appliances in Indonesian households: An analysis of lifetime use and decision-making in the purchase of electrical appliances. Applied Energy, 112, 981–987. doi:10.1016/j.apenergy.2013.02.036.
  • Singh, R., Mochizuki, M., Mashiko, K., & Nguyen, T. (2011). Heat pipe based cold energy storage systems for datacenter energy conservation. Energy, 36(5), 2802–2811. doi:10.1016/j.energy.2011.02.021.
  • Lin, L., & Strand, M. (2013). Investigation of the intrinsic CO2 gasification kinetics of biomass char at medium to high temperatures. Applied Energy, 109, 220–228. doi:10.1016/j.apenergy.2013.04.027.
  • Hamada, Y., Nakamura, M., & Kubota, H. (2007). Field measurements and analyses for a hybrid system for snow storage/melting and air conditioning by using renewable energy. Applied Energy, 84(2), 117–134. doi:10.1016/j.apenergy.2006.07.002.
  • Yu, L., Wang, Z., & Tang, L. (2015). A decomposition-ensemble model with data-characteristic-driven reconstruction for crude oil price forecasting. Applied Energy, 156, 251–267. doi:10.1016/j.apenergy.2015.07.025.
  • Clark, J., & Novoselac, A. (1970). Flow and mixed convection heat transfer in buoyant jets from floor registers. Energy and Buildings, 61, 140–145. doi:10.1016/j.enbuild.2013.03.006.
  • Markazi Province Meteorological Organization. (2021). Analysis of crop precipitation and its extreme events in Markazi Province during the statistical period of 1991-1992 to 2020-2021. (in Persian). Markazi Province, Arak, Iran.
  • Iran's Power Generation and Distribution Company (Tavanir), Tehran, Iran. Available online: http://www.tavanir.org.ir (accessed on February 2024).
  • Khabari, A., Zenouzi, M., O’Connor, T., & Rodas, A. (2014). Natural and forced convective heat transfer analysis of nanostructured surface. Proceedings of the world congress on engineering, 2-4 July, 2014, London, United Kingdom.
Contributions of Science and Technology for Engineering
Volume 1, Issue 3
September 2024
Pages 51-59

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History

  • Receive Date: 14 July 2024
  • Revise Date: 29 July 2024
  • Accept Date: 29 August 2024
  • First Publish Date: 01 September 2024
  • Publish Date: 01 September 2024

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